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U.S. MENT OF 0MEKM
AD-AO32 350
Laboratory Investigation of UndisturbedSampling of Cohesionless Material Belowthe Water Table
Army Eqier Weat EWidmet Stuti. Vidksrl Miss
Wc76
3307
IMSMACIMRPOR S-7&1t
LABORATORY INVESTIGATION OFSUNDISTURBED SAMPLING OF COHESIONLESS
MATERIAL BELOW THE WATER TABLEfby
U. S. Staffrd S. Cocpef
lusi &M Pac Imgas PiLdmabsVr
.O. it,* 631ic, Chickfg Aefs 39U1.80m
Cktcu r C j176
U. ocRmr CIO OME
Wn~ntwt IID. VA. 214
uakr C S 3114
UnclassifiedSECURITY CLASSIrICA ION 0. THIS PAGE '1.. 0.e. FO'.7-di
PAGE READ INSTRUCTIONSREPORT DOCUMENTATION PAEFORE COMPLETING FORM1. REPORT NUMIUR 2 GOVT ACCESSION 3 RECiPIENT'S CAIALOG NUMBERResearch Report S-76-1
4. TITLE (.d SbelfI.) S TYPE OF REPORT I PE'tIO0 COVERED
LABORATORY INVESTIGATION OF UNDISTURBED SAMPLINGOF COHESIONLESS MATERIAL BELOW THE WATER TABLE
6 PERFORMING ORG REPORT NUMBER
7 IuTHOR(.) 8 CONTRACT OA GRANT NUMBER(.)
Stafford S. Cooper
9 PERFORMING ORGANIZATION NAME AND ADDRESS 10 PROGqAM ELEMCNT PROJECT. TASK
AREA G WORK UNIT NUMBERSU. S. Army Engineer Waterways Experiment StationSoils and Pavements Laboratory CWIS 31145P. 0. Box 631, Vicksburg, Miss. 39180
It CONTROLLING OFFICE NAME AND ADDRESS 12 REPORT DATEOctobe~r 1976
Office, Chief of Engineers, U. S. Army OSA 19AE
Washington, D. C. 20314 73 Nu.O.SR4'r PAGES
14 MONITORING AGENCY NAME A Anf lESSI-I J,I11-1n It- (-..nr..Ihn* Off, ., IS SECUAiTY CLASS (o thi. lrporl)
Unclassified
I 7.r OCLASSIFICATION DOWNGRADING$.CmfOuLt
I6 OISTRIBUTIOCI STATEME^4T f.1 Ih,. Rop.t,
Approved for public release; distribution unlimited.
17 DISTRIUTION STATEMENT tol the a r* e e., tn fltlek 20. .1 dIfttn - 1- R eport)
1 SUPPLEMENTARY NOTES
1I KEY WORDS (Co-n' I n. on re,. d , t n.e.. .It -d ,Jn1tv A, block rlt.b'
Cohesionless soils Soil test specimensLaboratory tests Undisturbed soil samples
Sands
20 ABSTRACT (ContiIH-. o r.e*'O .. d. Ef n-e. - ry -nd Id..*I.5y h, blthb' .,-be,)
This report describes the results obtained in a laboratory program de-signed to evaluate the quality of undisturbed samples. A Hvorslev fixed-piston
Ksampler and drilling mud were used to obtain undisturbed sand samples in homo-geneously prepared specimens 4 ft in diameter and 6 ft high.
genstructxon of a honogetneous specimen 4 ft in diameter and 6 ft high is.o small feat. Various technJques were used during the course of this study
(Continued)
JDAN 1d73 DOO, oNov' S, IsoLETE / UnclassifiedSECURITY CLASSIFICATION OF THIS PAGE flr- lar. FnI,-,d,
x
Unclassified
SECURITY CLASSIFICATION OF T"iIS PAGE("On 0.f. Pn.ved)
20. A.ISTRACT (Continued).
for specimen preparation. As-built density determinations indicate that thevariation of placed density is approximately -1.5 to +2.9 pcf.
Undisturbed samples 3 in. in diarieter were obtained at different over-burden pressures. These samples were sealed with end packers and stored over-night in a vertical position. The following day each tube was placed in ahorizontal position in a wooden carrying rack, and the rop of each tube wasmarked for orientation purposes. Each tube was then tapped 50 t ies with arubber hammer to consolidate the material prior to handling. The tube wast.en cut into 6-in. segments for laboratory density determinations.
A sta'ittical comparison of the sampled density to the corrected "asbuilt" densy-v was conducted. This compar-soti indicates that the bamplingaccuracy is Uoithin +3.4 pcf 95 percent of the time.
II
.o', Unclassified
- s.'.'d[ '-:"
PREFACE
The study reported herein wap pertormed by the U. S. Army Engineer
Waterways Experiment Station (WES) as paLt of the Office, Chief of
Eigineers (OCE), Civil Works Research effort. This investigation was
authorized by OCE under rhe CWIS 31145 work unit entitled "Liquefa tion
Potential of Dams and Foundations."
WES engineers who were; actively engaged in this study were
Dr. W. F. Marcuson IlI and Messrs. W. A. Bieganousky, J. R. Horn, and
S. S. Cooper. The work was c¢nducted under the general supervision of
Messrs. R. W. Lunny and W. C. Sherman, Jr., former Chief, Earthquake
Engineering and Vibrations Division (EE&VD), Dr. F. G. McLean,
Chief, EE&VD, and Mr. J. P. Sale, C:i.ef, Soils and avements Laboratory
(S&PL). This report was prepared by Mr. S. S. Cooper ant internally
reviewed by Mr. S. J. Johnson, Special Assistant, S&PL. OCE technical
monitor for this investigation was Mr. Ralph R. W. Beene.
During the time this study was conducted RG Ernest D. Peixotto,
CE, and COL G. H. Hilt, CE, were Directors of WES. The Technical
Director was Mr. F. R. Brown.
.4
CONTENTS
Page
PREFACE ............ .............................. . . I
CONVERSION FACTORS, U. S. CUSTOMARY TO hETIIC (SI)
UNITS OF MEASUREMENT ........ ............. 3
PART I: INTRODUCTION .......... ....................... 4
PART II. TEST FACILITY....... ..... ................ 6
General ............. .......................... 6Stacked Ring Soil Container n, d Foundation .... ......... 6Ov.-rburden Loader ........ ...................... . i.11(nmpling Equipment ........ ..................... . 15
PART lIT: TEST PROGRAM ....... ..................... . 20
General ........... ........................... ... 20
Material Proper:ies . . . . . . . . . . . . . . . . . . . . . 20Specimnen Fteparation ....... .................... . 20Tesz Procedures ......... ....................... ... 23Test Results ............ ........................ 27
PAP.T IV: ANALYSIS ......... ........................ . 29
Variables Which Affect the Test Results ... ........... ... 29Comparison of Placed and Sampled Density Results . ...... .. 33
PART V: CONCLUSIONS AND RECU.MENDATIONS .... ............. . 48
Conclusions ......... ......................... ... 48Recommendations ........... ....................... 48
REFERENCES ............................ 50
TABLE I
PLATES 1-- 7
APPENDIX A: PEIROGRAPHIC ENIN, f!ON OF REID-BEDFORD ,UDEL SAUND
i2
j
CONVERSION 'croRs, U. S. CUSTOMARY TO METRIC (SI)
UNITS OF MEASUREMENT
U. S. customary units -)f measurement used in this report can be con-
verted to metric (SI) units as follows:
Multiply Bv To Obtaii
inches 25.4 millimetres
feet 0.3048 metres
poune (mass) per 16.01846 kilograms per cubic metre
cubic foot
pounds (force) 4.448222 newtons
pounds (force) per 6894.757 pascals
square inch
degrees (angalar) 0.01745329 radians
43
I
II
13
I
LABOIATORY INVESTIVATION OF UNDISTURBED
SAMPLING OF CONEStONLESS MATERIAL
BELOW THE WATER TABLE
PART I: INTRODULrION
1. Reliable determinations of in situ density of sands below tile
water table are essential to asses, the engineering properties of such
materials particalarly when liquefaction may be a problem. This problem
ha,: become more critical in recent years because more and more struc-
tures art being constructed which would cause catastrophic d~mage an!
loss of lifL if they failed. This is particularly true ,n the case of
nuclear p.,wer pl~ats and large dams. 3ecause of the critical n- ..urt of
this probl(m, the Corps of Engineers felt that the work they had done in
this area sooe years ago should be extendeci. 1,2 Earlier work conducted
at. the Waterw.r&s Experiment Stal-ion (WES) involved development of a
means to take inlisturbed sand samples using a fixed-piston saimpler and1
driliing mud. Reference 2 describes the results of fixed-pis:on samp-
ling in a large tank ;n which sana was placed at variable densities.
The dersity of the sand wirhin the sampiing tubes was compared with the
plaeetnent densities : " he sand in th_ tank.
2. Indirect mer, )d-; of determining the in situ density La.. been
used widely i:. the fiej. Work has ieen done ii thi area using -ndi-
rect methods such as the Standard Penetration "e,;t (St'T) o- the Dutch3- 7
Cone. Thee indirect methods are based on - crelations of penetra-
tiu;. resista-ce, oi'erbu!-den pressi e. and .elative dens'ty. They are
- wide.v used because they are hoth expedient and econorical means Lo
evaluate in situ density. Many enginee s from th.' start have que.tioned
Cnese corrclotions; however, they are s, ill widely uised. WES is now
evaluating the SfPT procedure in a stac--ed ring facility. The results
of these tests will be discussed in a .Av;sequLnt report.
3. In conjuaction with the Standard P,:netration Tests, WES has
taken undisturbed fixed-piston samples in the s:tked ring facility.
These samples were taken to the laboratory and iabor.to;rv density
4
j determina-ions made. These sampled denskties ware then compared with
the as-built density of the specimens. This report will Jiscuss these
results.
,W
PART II: TEST FACILITY
General
4. The major components of the test facility are a 4-ft-diam*
stacked ring soil container, a massive, reinforced-concrete founda:ion,
and loading equipment for applying pressure to the top of the soil
specimen. The stacked ring container was originally designed for use8
with 3 dynamic air overpressure loader, bit was adapted to this study.
Tile static pressure equipment used to simulate overburden loading was
designed for the purpose. A srhem..tic of the test facility is shown in
Figure 1. Figure 2 shows the facility ready for sampling operations.
The major components of the test facility as well as the sampling equip-
ment u'ed are described in detail sub-.quentlv.
Stacked Rin Soil Container - .nd .Foundation
The stacked ring soil container u.ls developed from a study
conducted by Dr. M. Juul lvorslev 9 and is Aimilar to a smaller diameterInst~ute.10
device used at Stanford Researb Inst'tute. The WES stacked ring soil
contairer was developed to minim4Le the wall friction, or silo, effect
which is inherent in rigid wall containeLq and which causes an unde-
sirable ceduction in soil stress with increasing container depth. A
reduction in stress with increased depth is the reverse of in situ con-
ditions and is particularly significant i. rigid wall containers whose
frictional effect can reduce the soil stress due to dead weight by as
much as 40 percent at a deth equal to tle sp',cimen dameter.1 1
Stresses fromt aoplied loads can likewise be reduced by more Jhan one-
11half at a depth of one diameter. Hence, the impetus to minimi .e wall
friction effects by means of a vertically flexible coreainer.
6. The WES stacked ring container consists of a srack of i-in.-
high by 4-ft-ID steel rings which are separated with 3/16-in.-thick
rubber spacer rings. Container height is controlled by varying the
number of rings (steel and rubber) in the stack. Grooves are provtded
A table of factors for converting U. S. customary units of measure-
erent to metric (Si) units is presented on page 3.
6
REACTION BEAMS
6-IN..ID PROTECTIVE a nSLEEVE FOR CENTERHOLE IN LOADING HEAD
HYDRAULIC RAMS
CONCRETE PEDESTAL 2
3 IN. -ID PROTECTIVE L NOING HEAD
SLEEVES 3, FOR PERIPHERALHOLES IN LOADING HEAD -.. -, WATER-FILLED
SUMP PUMP '(ha RUBBER BAGFLOOR LEVEL W H
WATER SUACEATE
STACKED RINCSPECIMEN CONTAINER CABLE WAY
STAIRWAY
II SPECIMEN BOTTOM
G-', Z-W.PACTE2
II . -EFR
II
II _ D- BEDF'R-D SA% C
S'r ANDARD CONCRETESAND BLANET T
% S T, VATER A-5
Figure 1. Test apparatus
7<
-42
Figure 2. Test facility with drill rig in place
8<
Iin the steel rings to accept mating keys molded in the rubber spacers.
The rubber spacers provide the desired flexibility in the vertical
direction while the steel rings serve to restrict radial deformation of
the specimen. Calculations based on typical sand specimens indicate
that radial deformation should not exceed 0.024 percent for a maximum
vertical applied load of 300 psi. This degree of radial restraint is
sufficient to provide an acceptably analogous medium for representing
field, i.e., uniaxial strain, conditions at depth.
7. During Test No. 4 of this "tudy, micrometer measurements of
vertical deformation were made on several rubber spacer rings in the
stacked ring container. When the specimen was loaded to 80 psi, each
rubber spacer typically compressed 0.0035 in. In subsequent tests,
conducted on an empty 2-ft-high section of st:cked rings, it was deter-
mined that an average deformation of 0.0035 in. corresponds to a verti-
cal load of 750 lb on the container. Thus, the maximum load transmitted
to the soil container via soil friction in Test No. 4 is assumed to be
750 lb, or 0.5 percent of the ttal vertical force of 144,765 lb
applied. The remaining load, 99.5 percent of the tctal load, was
transmitted to the specimen. These data clearly indicate that the
stacked ring soil container is effective in minimizing wall friction or
silo effects.
t 8. A cross-sectional view of typical steel and rubber rings,
showing the nominal unstressed dimensions for each, is presented in
Figure 3 For this investigation the stacked ring container was used to
confine 6-ft-high sand specimens.
9. The massive concrete foundation of the test facility was de-
signed to withstand the vertical forces developed in dynamically loading
4-ft-diam specimans with overpressures to 300 psi. Consequently, static
loadings to 300 psi in this study posed no problems. The top of the
main foundation Is at floor level with two loader-support pedestals
extending 4 ft above the floor. A specimen preparation well is located
between the support pedestals and extends from floor level to a depth
of 6 ft into the foundation. From the bottom of the specimen prepara-
tion well a 4-ft-diam specimen hole extends 6-1/2-ft through the
9
" RUBBER SPACER
SPECIMEN A
A - LK-STEEL RING
A 3 16'
SA
AAI
Figure 3. Cross-section view of typical steel
rings and rubber spacer rings
foundation to the ground beneath. Approximately 5 ft of this hole was
stemmed with highly compacted sand and the upper 1-./2-ft of the hole
was used to install a graded filter so that the Zesc specimens could be
submerged from the bottom up. The filter was constructed in three
3-in.-thick layers, grad,1.g from a base layer of l-in.-diam crushed
rock to a tup layer of "pea" sized rock. A 1/2-in.-diam perforated
garden hose was coiled in the base layer of the filter and e::tended to
the floor level via a cableway provided in the foundation. Thc top
filter layer was covered with a single thickness of cotton fabric, and
the remainder of the 6-1/2-ft-deep specimen hoe was stemmed with com-
pacted sand to the bottom of the specimen preparation pit. The test
specimens were constructed over the filter and occupied the 6-fL-deep
space between floor level and the bottom of the specimen preparation
well, as shown in Figure 4.
10
I I
Figure 4. Typical specimen in thespecimen preparation well
Overburden Loader
10. "he overburden loader basically consists of a ram and beamreactioti assembly, a cylindrical steel loading head, and a water-filledpressure-equalizing bag. The assembled overburden loader is shownbeing lowered onto a prepared specimen in Figure 5. Vertical load isapplied to the loading head by the hydraulic rams. The water bag isplaced between the loading head and the specimen, and serves to uni-formly distribute the vertical load applied to the specimen.
11. The beam assembly consists of four steel box members whichwere welded to crossmembers into a single unit. Three double-acting8-in.-diam hydraulic rams were welded to the bottom of the beam assembly
11
--- -'------#---
- - - - -
I
Figure 5. Overburden loader being
lowered onto specimen
so that the cylinder end of each tam is founded on two beams. The rams
are individually driven by three manually operated hydraulic pumps
mounted on a portable console, shown in Figure 6. Hydraulic pressure
delivered to each ram is monitored with (onsole-mounted bourdon gages.
12. The overburden head is an internally braced 46-in.-diam by
18-in.-high hollow steel cylinder. Its bottom surface is a machined
48-in.-diam flange which contains a peripheral "0" ring seal. As shown
in Figure 7, three 3-in.-ID and one 6-in.-ID steel sleeves penetrate the
loading head vertically. These sleeves e-<tend through holes provided
in the water bag and penetrate approximately 2 in. into the specimen
beneath. They se-ve to guide the samplers and to pro .ect the water bag
during sampling and reaming. The fiberglass-reinforced rubber water
bag, shown in Figure 8, is nominally 48-in.-diam by 3-in.-thick, and is
filled by two tubes which exten2 upward through holes provided in the
12
'A,-A
la-
Figue 6.Contol cnsol
13I
A
I TOP VIEW
6-ilN. -C 10I.
ITL
SECTION A -A SCALE
0 6 1e 24 IN
Figure 7. LoC.3tianof steel sleeves ir, loadinag head
Figure 8. Fiberglass-reinforced water bag
MW loading head. Bag pressure, or vertical stress applied to the specimen,
is measured with a calibrated bourdon gage connected to the filler tubE.
When in the loading position, the bag is confined radially by a 6-in.-
high, machined steel :dlar which rests on, but is not attached to, the
top steel ring of the stacked ring container. The "0" ring seal in the
flange of the loading head prevents metal to metal contact with the
collar. With this arrangement, no live vertical load is applied direct-
ly to de stacked ring cc¢itainer, although some vertical load is trans-
mitted to the rings via soil friction.
SRa.mpi j i ui ment
13. The drill rig used in this study is a commercially available,
skid-mounted Acker Teredo Mark II Soil Sampliag Drill. Low overhead
clearance. in the laboratory precluded the use of a derrick, so lifting
15
tackle for the drill rods was secured to rafters in the ceiling. For
& sampling ard drilling, the rig was elevated on a platform built level
j with the top of the loader-support pedestals. A port ble mud pump sup-
plied with mud from a sump atop the loading head provided mud circula-
tion during reaming. The mud sump was formed biy encircling the upperI part of the loading head with a thin metal band. as shown in Figure 9.
i .. Undisturbed samples were taken w. n a Hvorslev 3-in.-ID
thin-wall, fixed-piston sampl. r. Nomin,:l diienFions for the 16-gage
sample tube include a 2.97-in..-ID cutting edge, a taper angle of 10
degrees on the cutting edge, and an area ratio of 11 percent. 13 Thecotm" !te sa.mpler it, shown in Figure 10, and a schematic of the sampler
is shown in Figure 11. The drill rod used in sampling vas 2-in.-OD "N'
size. The WES-modified fishtail bit shown in Figre 12 was used for
reaming. The bit itself is commercially available. However, special
baffles were added at WES to direct the flow if drilling mud upward,
away from the bottom of the borehole. Thus, disturbance of the under-
lying material by circulating mud is minimized when reaming or drilling
to sampling depth.
-I- t
: 16
I'
- - ~
I -~ -
-
IIII Ij I II #-~---
R
I= I
*
i
Figure 9. Mud suxnp atop loadftzg head
IIII
I
Figure 10. Hvorslev 3-in. fixed-piston samplei
I II F
x
4- ftf S~xt r_ CAP
W 6 )LI.. -f -SI qjt- C - OL a?
S..4
SAMIRL A
5- IN. ADAPTER
UP 94*9. to f 5-IN. PISTON TOP
A-. Nz.Ca
drawing~3 so. 1253r rvsd9 cs3
18f o .
Figure 12. WES-rnodified fishtail bit
19
PART III: TEST PROGRAM
General
15. The test program consisted of undisturbed sampling and stan-
dard penetration testing on sevet, 4-ft-diam submerged specimens of a
locally available sand. Results of the penetration testing will be re-
ported sep3rately and only the undisturbed ;ampling will be described
herein. Ir the course of the study 24 undisturbed samples were obtainedfrom specimens placed at relative densities, D , ranging from 18 to
r
60 percent.
Material Properties
16. The material used in this study is commonly termed Reid-
Bedford Model Sand and its properties have been well documented in pre-
vious studies conducted at WES. However, a further series of material
property tests was conducted for this investigation using procedures
14outlined in EM 1110-2-1906. These tests included determinations of
maximum and minimum dry density, compaction, and gradation. Typically,
maximum and minimum dry density were 107.1 and 88.7 pcf, respectively.
A representative gradation curve for the material is shown in Figure 13.
In addition, a petrographic examination was performed on the sand. Re-
sults of this examination are presented in Appendix A.
* 17. Based on these data, Reid-Bedford Model Sand is characterized
as a uniform, fine sand (SP) comprised predominantly of subrounded to
subangular particles.
Specimen Prearat ion
18. Specimens uere placed i, the stacked ring container by
raining. A rotating sand rainer was used to construct the first four
specimens in the test program; however, it was not possible to build a
specimen of low relative density (i.e., D < 35 percent) with thisr
rainer. A second sand rainer of similar design, shown in Figure 14,
was built to provide a wider range of relative density. It was used to
20iI
JLW As U*5Uvo~ IND~ su
fq~u Irv.~4 .
= a
-~C -- L 4L~
z U _
0
~4- -
InI
01~
-- * 0 -i--0-0t--OmV 4-1 t% c
LU13 A$i VIM1 IND4-
-~ 7 /
4 -S4
Figure 14. Rotating sand rainor
place the remaining specimens. The two rainers differ principally in
the number and arrangement of flexible tubes and in the diffuser plate
incorporated in the second rainer. The diffuser plate facilitated ad-
justing the sand flow so the second rainer produced a more level speci-
men surface. With this rainer. density is primarily controlled by regu-
lating the free fall distance betieen the diffuser plate and the speci-Ymen surface. A relative density as low as 18 percent was achieved with
Specimen No. 5.19. Specimen construction was begun by first filling the rainer
reservoir with enough sand to produce a 6-in.-thick specimen lift.
Then, the rainer was lifted and suspended at the desired height above
the specimen by an overhead traveling crane, lift density was controlled
by varying the height of drop from the rainer to the specimen surface.
In general, higher densities required greater heights of drop. The
rainer was rotated at approximately 15-20 rpm during raining to evenly
distributu the sand over the specimen surface. This placement procedure
was repcated ror successive lifts until a 6-ft-high specimen was built.
When the last lift was placed, the specimen surface was screeded level
with the top of the stacked ring container.
Test Procedures
20. Finally, the specimen was submerged from the bottom up by
admitting water to the perforated hose coiled in fhe filter beneath the
specimen. The water flow through the hose was controlled so the water
level in the specimen preparation pit rose from 3 to 6 in. per
hour. The stacked ring container and preparation pit are connected by
a cableway in the foundation and the stacked ring container is permeable
so the water tended to rise simultaneously in the specimen and pit. As
the water level rose, some air was observed to escape from the specimen
by bubbling through the walls of the stacked ring container at ring-
gasket interfaces.
iensity measurements
21. Density measurements for the first four specimens consisted
23
of weighiug the material placed in each lift aud then computing an over-
all density after the final lift was placed. To evaluate placement uni-
formity, incremental density measurements were takeit in the remaining
specimens using a WES-developee )ox density device. The box density £
device is shown in use in a cyp cal specimen in Figure 15. Generally,
box density measurements were made in each 6-in.-thick lift placed.
Overourden loading
22. In preparation for testing, the overburden loader was assem-
bled atop the specimen. Assembly was begun by fitting the overburden
lead with a deflated water bag and then lowering it into the 4-ft-diam
by 6-in.-hign steel ring used to confine the periphery of the water bag,
as shown in Figure 5. The loading head was positioned within 3 in. of
the specimen surface and water was introduced into the bag until it
filled this space. This completed the assembly process, and permitted
the application of overburden pressure simply by pressuring the rams.
23. Overburden pressures of 10, 40, and 80 psi were used in the
test program. A diagram of the typical loading sequence applied to the
test specimens is shown in Figure 16. Horizontal leveling of the load-
ing head was accomplished by individually pressurizing the hydraulic
rams. Each pressure increment applied was maintained for approximately
30 minutes prior to sampling so pore water pressure could dissipate
and conditions within the specimen could stabilize.
24. During testing there was some! variation in overburden
pressure applied as a result of the penetration, sampling, and reaming.
Typically, the gage monitoring overburden pressure indicated a 1-psi
drop for each 18-in. drive during penetration testing, and an addi-
tional 3- to 5-psi decrease when the splitspoon was withdrawn from
the specimen. After the splitspoon was withdrawn, pressure was re-
stored to the desired level. During reaming, the applied pressure
dropped approximately 1 to 2 psi, and after withdrawal of the un-
disturbed sampler tube the pressure dropped about 2 to 5 psi. In both
instances pressure was restorzd to the desired level before continuing
the test.
24
59
Figure 15. WES box density device in use on a typical specimen
-80
U701-
u60
a. S0O
z0 40
0: 30
o 20
310a.
TIME
LEGEND
TEST SEQUENCEI -- SAMPLING INTERVAL
Figure 16. Typical load--tim~e history
Undisturbed sampling
25. Undisturbed sampling was conducted in corjunction with stan-
dard penetration testing. The sampling was to be done in stages to con-
form with the penetration tests planned, and all of the undisturbed sam-
ples wlere taken through the center hole in the loading head and along
the cylindrical axis of the specimen. Sampling was originally planned
at overburden pressures of 10, 40, and 80 psi; however, this often
proved to be impossible because the drill rig employed did not develop
sufficient force te drive the sampler at pressures greater than 10 psi.
Consequently, most of the undisturbed 3-in.-OD samples were taken with
10 psi applied to the specimen. After each sampling operation, the
center, or sampling, hole was stemmed with pipe before penetration tests
were conducted in the peripheral holes. This practice was adopted to
prevent hole closure and concomitant reductions in lateral pressure.
26. The test sequence was generally as follows:
a. With 10-psi pressure applied, the first tube was driven2 ft into the specimen through the center hole in theloading head. After withdrawal, the center hoe wasstemmed with pipe to 2 ft in depth.
b. Splitspoon tests were conducted in a peripheral hole to atotal depth of 6 ft, after which the peripheral hole wasstemmed.
c. The stemming pipe was withdrawn from the center hole andthe overburden pressure was raised to 40 psi. Next, thehole was reamed to a depth of 2 ft and the second undis-turbed sample was taken from 2 to 4 ft in depth (bytemporarily reducing the overburden pressure applied, ifnecessary). Afterwards, the hole was stemmed to 4 ft indepth.
d. Penetration tests were conducted in the second peripheralhole as per step b, above.
e. The last undisturbed sample was taken from 4 to 6 ftin depth 's described in step c except that, conditionspermitting, the last sample was driven with 80-psi over-burden pressure applied to the specimen.
f. Penetration tests were conducted in the third peripheralhole, concluding the test.
27. Sampling and incremental density determinations were carriee
out in accordance with procedures outlined in references 12 and 13. The
26
undisturbed samples were sealed with end packers and stored overnight in
a vertical position. The following day, the tubes were placed in a
horizontal position in a special wooden carrying rack. The top of each
tube was marked so that this orientation could be maintained throughout
the density determinations. Each tube was then tapped 50 times with a
rubber hammer on the top surface to consolidate the sand (25 blows in
one direction, repeated in the opposite direction along the t':be). The
tubes were later cut into 6-in. segments for density determinations.
Density determinations were also made on shorter sections if enough addi-
tional material remained after the tube was cut into 6-in. segments.
Test Results
28. A total of 71 incremental density determinations were made
on 24 undisturbed samples. These data, together with placement densi-
ties, are shewn in Plates 1-7 for each test conducted. The placed and
sampled dry density results are plotted versus depth in the specimen. A
scale of relative density, D , is also provided at the top of each~rplot. Each sampled density increment is identified by two numbers, for
example 1-3. The first number indicates the sequence in which the sam-
ples were taken, i.e., the number one denotes the first sample taken.
The second number indicates the tube increment from waich the density
determination was made; in this instance the third increment. The sym-
bols for incremental density are scaled to represent the length of the
tube increment from which the density determination was made.
29. In each plate, the variation of sampled density from placed
density is also plotted versus depth. Note that a density variation is
plotted only for those sample depths where both a placed density and a
sampled density were available. Based on this criterion, a total of 65
density variations have been plotted. The density variations plotted
for specimens 2 and 4 constitute a special case because the average
placed density shown for these specimens was obtained from total weight
and volume measurements rather than incremental box density measure-
ments. These specimens were built early in the study when placement
27
techniques were being developed and the problem of vertical density
variations had yet to be addressed. These data, comprising 22 of the
65 density variations plotted, have been included oaly for gross com-
parisons since the implicit assumption of an average (uniform) vertical
density i,; known to be incorrect. Negative values on the plots indicate
that the sampled density determination showed a lower density than the
placed density; positive val!es indicate the reverse. Various factors
which affect the comparison of placed and sampled densities obtained in
the study will b,2 examined in the analysis section of this report.
30. Also shown in the plates, where applicable, are plots of
force on the sampler versus depth of penetration. These data were
computed from drill-rig, hydraulic pressure measurements recorded for
to the sampler, the rig hydraulic pressure was multiplied by the total
working area of the two hydraulic rams pushing the sampler. When push-
ing the sampler in dense material, the rig pressure frequently exceeded
the range of the bourdon gage used to make the pressure measurements.
The maximum force of 6300 lb shown in plots may thus be substantially
less than the actual force applied to the sampler. Sampler force is
plotted as a dashed line to indicate some uncertainty in accuracy.
28
IPART IV: ANALYSIS
Variables Which Affect the Test Results
31. It is obvious that an assessment of sampling accuracy is no
better than the accuracy with which specimen conditions can be deter-
mined at the time of sampling. Given the nature of soil materials and
the current state of the art in soil measurements, it is equally obvious
that test results will be accurate only to within certain limits. Ac-
cordingly, it is necessary to evaluate by the most practical means any
variables which are believed to influenc test results significantly.
Considering the test procedures cmployed in this investigation, the Iost
significant variables to ;be evaluated before sampling accuracy can be
assessed are-
a. Accuracy of box (placed) density m asurements.
b. Uniformity of specimen density at the depth of measure-
ment.
c. Placed density variations due to the overburden pressures
applied.
32. The first variable, i.e., tie relative accuracy of the box
density measurements, has been documented on dry, Reid-Bedford sand in
earlier studies. 1 5 Based on these studies, the box density measureme:.ts
made are believed to be accurate within ±0.2 pcf.
33. The secn- variable, uniformity of specimen density, was
initially considered only in terms of vertical variations. It was de-
sired to monitor specimen density control by an expedient means so box
measurements of lift dansity were undertaken. In the course of later
testing, it was found that placed density also' varied laterally by a
16maximum of about ±3 pcf from center to edge of the specinten. This
condition is believed to have resulted from using a rotating sand rainer
to place the specimens. Improved methods for placing the sand have16
since been developed and will be reported separately. Nevertheless,
it is believed that all of the specimes reported herein s iffered some
lateral variation in dersity from the center (where the sample was
29
taken) to the radius of the peripheral hole- (between which the box
density measurements were made). It is prohable, then, that the placed
densities reported did not accurately reflect densities where the sam-
ples were taken, and that the variation was typically on the order of
±2 pcf.
34. A direct measurement of specimen deforniition would have pro-
vided a convenient way to assess the third variable, placed density
increase due to overburden pressure. This change in density is not
otherwise accounted 'ot because placed density was measured before over-
burden pressure was alied and the samples were taken later. Urfor-
tunately, measurementF f specimen deformation under load were not con-
ducted during this study because the physical arrangement of the test
apparatus is ill suited to the purpose. Also, the absence of a rigid
boundary at either end of the specimen may adversely affect the accuracy
with which such measurements could be made. Nevertheless, it is recog-
-nized that density changes occur as a result of loading, and that
sampled densities should properly be compared with placed densities
corrected to reflect the change. In order to indirectly assess the sig-
nificance of density changes under load, one-dimensional consolidometer
tests were conducted on saturated samples of Reid-Bedford sand. Results
from these tests are shown in Figures 17, 18, and 19 and these results
were used to derive the correction curves shown in Figure 20 which re-
late placed density and density increases to overburden pressure ap-
plied. The density corrections derived, the variations between placed
density (corrected and uncorrected) and sampled density for each test,
and other pertinent data are summarized and tabulated in Table 1. The
density corrections for overburden pressure applied ranged from 0.19 to
1.82 pcf, and averaged about 0.7 pcf. The correction values postulated
should be reasonably accurate, considering the method of derivation and
its applicability to test conditions.
35. To summarize, the three variables and their probable in-
fluence on the accuracy of placed density determinations are as
follows:
30
414
00
0 ) .z
U)'
0 0
I-
o -cc.Q.=2f
r~ a,
------ ------ -----
0 . .
or Z 3t
- II
0 Lw
10 0
IV~0 0 0
4-
V
~ -4 tr
0
0
O-j 0A'.)C
c' -
0
AJ -4
j-10' 0.
i -
-Sd d 3
te'SS3eSd NO *i"N
II
Probable Range of Vriation iVariable pcf
Box density measurement error ±0.2
Specimen nonuniformity ±2.0
Density change due to overburden pressure +0.7 pcf (average) I
I
The cumulative upperbound error from all three variables would thus be
+2.9 pcf and the corresponding lowerbound error would be -1.5 pcf. The
positive (+) bias is assumed to represent overburden pressure effects. I|
Comparison of Placed and Sampled Density Results|
36. The data presented in Plates 1-7 and summarized in Table 1
were used to make a gross comparison in the form of the distribution
plot shown in Figure 21. The ordinate of the plot in Figure 21 shows
frequency of occurrence of a given density variation out of the 65
density variations obtained. The abcissa of the plot is variation from
placed dry density in both pcf and gm/cc units. Density variations were
rounded off to the nearest 1/2 pcf (0.008 gm/cc) before plotting. The
arithmetic mean of the 65 density variations is 1.1 pcf (0.016 gm/cc);
this is consistent with the assumption of positive (+) bias from over-
burden pressure effects. The standard deviat!. n iz 1.7 pcf (0.0271
gm/cc). Two of the density variations recorded, those at -6 and -10 pcf,
respectively, are certainly suspect and were not considered in the cal-culations. While no specific reason can be cited, it is assumed that,
the samples in question were inadvertently disturbed during either the Icutting or meastrement processes.
37. 1he erratic portions of the plot shown in Figure 21 are at
least partly due to the limited data population obtained; however, it
is also probable that the test variables described previously have some
effect as well. To investigate the data trend over a range of placed
densities a second plot was prepared as shown in Figure 22. In
Figure 22, placed dry density is plotted on the acissa and the incre-
mental sampled . density is plotted on the ordinate. Relative density
scales are also pro_-* Inr reference on both axes. Only the data from
are ro,., on axes Onl
AR T.,MET C %EAN I PCF
12 - ~NOTE 0Ev AT ON$ OF - '.'2 AND -6, I D-SREGARDEO FORTHESE CA-C-AT ONSI- STANDOARD DEvAT ON I PCV
'0
U
0
z6
4
= 2
0
PC F
-0ie -010 -005 0 005 0 10
VARIANCE OF SAMPLED DENSITY FROM PLACCO DENSIT'V
Figure 21. Distribution of densir', variations
RELATIVE DENSITY D. PERCENT
10 20 30 40 50 60 70106 I I I
90
1040
80
0
102 -
100 0
I-.d
LINEAR REGRESSION FIT 0 60 6Z TO TEST DATA 0
D 98 - Y r 0.803X + 19.475 00
I 0 z01 0 7s~oo
0 ILI
96- 001 0
-440"
0 0
0 7o94 000 0
04
40 0
92 2
PERFECT SAM1PLING I CORRELATIONBETWEEN PLACED AND SAMPLED DENSITIES)
90 -c90 92 94 96 98 l1 102
u .PLACED DRY DENSITY ad PCr"
Figure 22. Comparison of as-placed and sarmpleddensities from tests 5, €,7, 8. and 12
35
tests 5, 6, 7, 8, and 12 were used in Fi.gure 22 lb. cause the placed
density in tests 2 and 4 was determined from bulk rather than incremen-ml tal box density measurements and did not provide the desired directcomparison. For reasons given previously, the data points at -6 and
-10 pcf were not plotted in Figure 22. A linear regression analysis was
performed on the data shown in Figure 22 and the linear fit derived is
indicated by a dashed line in the plot. The equation of the line is:
y = O.8 0 3x + 19.475
* where
y = sampled density
x = placed density
The coefficient of corteiarion for the linear fit to the data is
r = 0.83 and the coefficient of determination is (r ) 0.69.xy xyFor a high lcvel of confidence in fit, it ie generally accepted that the
coefficient of correlation should be 0.90 or more. On this basis, a
coefficient of correlation of 0.83 may be termed indicative rather than
definitive, so there is some level of uncertainty associated with the
data trend shown in Figure 22. For comparison, a solid line was a3ded
to the figure to show the ideal correlation between placed and sampled
density which could be achieved with perfect sampling (providing no
other variables were influencing the results). The data zrend in
Figure 22 does indicate that sample densities tend to exceed placed
densities at placed relative "ensities iess than 60 percent, and that
the reverse I.s true for placed densities more than 60 percent. This
trend generally agrees well with the work of earlier investigators,2
and has been ascribed to the mechanical effects of sampling, that is,
sampling tends to slignIly coisolidate loose material and to loosen
dense material. It should be noted that the data presented in
Figures 21 and 22 are a comparison between as-placed and sampled densi-
ty, and that other effects, such a3 the three variables previously men-
tioned, are not considered.
38. Two of the three variables previously discussed, the box
36
=1
Ao . -.. , ' -. - ... ... . . - v - -
density measurement errors and the lateral density variations, are ran-
dom in nature. Since these variations are random it is di'ficult to
evaluate their effect on test results excep, in general terms. The
third variable, density increases due tD overburden pressure, is sys-
tematic and its effect on the comparison of placed and sampled densities
can be assessed with reasonable accuracy from the data tabulated in
Table 1. To this end, the corrected, olaced density data from Table 1
4were used to construct Figures 23 and 24, which were plotted in the same
way as Figures 21 and 22. Comparing Figures 21 and 23, it can be seen
that the primary effect of the overburden corrections is to shift the
mean deviation line in Figure 23 towards the vertical (zero) axis while
the standard deviation remains relatively unchanged. This is consistent
with the previous assunpticn of systematic variation. Comparing
Figures 22 and 24, it can be seen that the linear regression fit to the
data in Figure 24 is a line which is closer to the line of perfect samp-
ling. Both regression fits exhibit a similar trend in slope; however,
the linear fit in Figu.e 24 crosses the perfect sampling line at a
reltive density oi -bout 36 percent. Thct is a pronounced scatter of
data points in both plots, particularly for those points falling in the
placed relative density range between 50 and 60 percent. The coeffi--
cients of correlation and determination for Figurp 24 are 0.82 and 0.67,
respectively, and these are nearly identical w-. i similar values from
the regression fit presented in Figure 22.
39. Since these data and earlier work2 exhibit a generally
similar trend, Figures 25-31 were prepared for further comparisons. In
Figures 25-31, the dersity variation of sample increments from placed
density at the same depth is plotted versus increment location in the
sample tube. The abcissa of each plot is dry density; the ordinate is
scaled as distance from the bottom of the sampling tube to the center
of eaca density increment. The figures include information on sample
depth within each specimen, sample identification number, and the over-
burden pressure at which the sample was taken. The uppi, plot in
Figurc:, 25-31 shows sampled density variations from as-placed density;
the lower plot shows variations from placed density which has been
37
____ ___ ____ ___ ___ ____ ___ __ _ ___ ___ ____ ___ __7
14101, -8ARITHMETIC MEAN 0.15 PCFL NOTE OEVIA-IONS OF -10.712- AND -7.2 PCF DISREGARDED
I FOR THESE CALCULATIONS.
IllI STANDAFD DEVIAT!ON 1.67 PCF
10
wU
U8
U- 70
Uz6w
4
3 7
2
0-12 -10 -9 -8 -7 -3 -2 -1 0 I 2 3 4 5 6
PC F
-0.16 -0.05 0 0.05 0.10
GM/CC
VARIANCE OF SAMPLED DENSITY FROM PLACED DENSITY(PLACED DENSITY CORRECTED TO ACCOUNT FOR OVERBURDEN PRESSURE)
Figure 23. Distribution of corrected density variations
38
RELATIVE DE''STY DR PERCENT
10 20 30 40 50 60 7010 6 ..........
1040
-80
02 0
70
0 z0100 w
0 U
0"Id0
> 0 80 (t
z
0 -LINEAR REGRESSION FiT 0 w
TO CORRECTED TEST % a
OCATA 0 50 wL 1 J Y 0 90SX Q -J I-Srx, - 0082
00 00 0r
- 40
0 0
0 0
92 20
PERFiCT SAMPLING I I CORRELATION
BETWEEN PLACED AND SAMPLED DENSITIES,
90 II I I90 92 94 go 98 1OO 102
CORRECTED PLACED DRY DENS TY .d PCF
Figure 24. Comparison of placed density, correctedfor overburden pressure applied, with sampled densi-
ty from tes ; 5, 6, 7, 8, and 12
39
SAMPLE VW.RIATION FROM PLACED DENSITY36 7v I
Z30
0I
0Z 12
-j A
it 0
(n I DA
0 00- -5 -4 -3 -2 -1 0 1 2 3 4I I
0 0_I
0
Is .t J - -------- -
,.,i Io
SI
(0 I 24i i0z J
-5 -4 -3 -2 - 0 2 3 4
DRAY DENSITY ' 7
LEGENDSAMPLE DEPTH IN OVERBURDEN
SYMBOL NO SPECIMEN, IN PRESSURE, PSI
0 1 0-27 10a 2 30-48 40a 3 48-65 80
Figure 25. Density variation versus location insample tube from specimen 2, D r 40 percent
l r
l '=,40<i ,
Wk,
SAMPLE VARIATION FROM PLACED DENSITY
30__ ___ _ __ - __
24 1
0 Z -. z ~l
w -
000 Z
-5 -4 -3 -2 -1 0 I 2 3 4 5
SAMPLE VARIATION FROM PLACED DENSITYo0 (CORRECTED FOR OVERBURDEN PRESSURE)
II I
zI ,(U3
10 2 4
0 -I
DRYDENI '7Do PF
0 0 02
5 -4 -3 -2 -I 0 2 3 4
DRY DENSITY 4d, pe n
LEGENDSAMPLE DEPTH IN OVERBURDEN
SYMBOL NO SPECIMEN$ IN PRESSURE, PSI
0 1 0-23 100 2 23-41 40
a4 42-65 60
Figure 26. Density variaLion versus location in
sample tube from specimen 4, Dr 35 percent
4:1<
II
SAMPLE VARIATION FROM PLACED DENSITY38
I-I0 1
8-
o- zw- 6 --
I Aj(n a:U 0_0
0 - 5 -4 -3 -2 -I 0 I 2 3 4
0.SAMPLE VARIATION FROM PLACED DENSITY
0- (CORRECTED FOR OVERBURDEN PRESSURE)IL 3 6 I
00
w - 30 .. ; - . . .. - ---
00!z UJ
fA 0 0
0 I ,AG 0
6 0
0 It
-5 -4 -3 -2 -I 0 I 2 3 5
ORY DENSITY '7 d PCF
LEGEND
SAMPL E DEPTH IN OVERBURDENSYMBOL NO SPECIMENI IN PRESSURE, PSI
0 I 0-24 10
0 2 24-48 40
A 3 48-72 80
Figure 27. Density variation versus location insample tube from specimen 5, D = 20 percent~r
SAMPLE VARIATION FROM PLACED DENSITY381 SI I
30 I II' bI ,-10.24
I A
2 0
0 Z 52 -4 - -2 0- -1 2. . 3 4- 5 .. .
-wI
0 __ _ _ _
'2 SAMPLE VARIATION FROM PLACED DENSITY
04,,
Ul (CORRECTED. FOR OVERBURDEN PRESSURE)
0-z 0
zw I
W) 0 24 I
-10.7 -
0-
a 0-
I I 1 0 IG__ IT --- 1-- -- I
____,__
-5 -4 -3 -2 -1 0 1 2 3 4 5
DRY DENSITY PCF
LEGENDSAMPLE DEPTH #4 OVERBURDEN
SYMBOL NO SPECIMEN IN. PRESSURE, PSI
0 1 0-21 10a 4 44-6C 80
II Figure 28. Density variation versuis location in
sample tube from specimen 6, 1) 55 percent
• :. t Q- i f 4t
SAMPLE VARIATION FROM PLACED DENSITY36 !T I t-
24
-.. 1
52
t. ,6 Zl •0 • -
-5 -4 -3 -2 - 1 0 2 3 45
wo _ 60 -- * -..... - 0
2w
O - " -3 -2. . . . 0.I 3 _l'- SAMPLE VARIATION FROM PLACED DENSITY
11- (CORRECTED FOR OVERBURDEN PRESSURE)
0 -
7 -7.2
-5 -4 - 3= -2 - 0 2- -3 ...
k: Z
0 II
0 -- 4 -0
t0
t m s e 7 I 0 5
6 6 30-4 4
S4 -3 -2.1 0 1 2 804
SYMBOL NOb froPspec MEN, IN = 5PvRERts
r
44<--------
SAMPLE VARIATION FROM PLACED DENSITY
II -- -4 -- I
I°I, i
a Z
I W
Ai
I- A
"Z 00- -5 -4 -3 -2 -1 0 1 2 3
o SAMPLE VARIATION FROM PLACED DENSITY
M (CORPECTED FOR QVERBU.'---,;; PRESSURE)
LL 36_ _ __ I_
,., 30 ---1 --
Li 30i :
0 1 __ _ _ _
S -4 -3 -2 - 0 2 3
DRY DENSITY -fd PcFr
LEGENDSAMPLE DEPTt, IN OVERBURDEN
SYMBOL NO SPECIMr N IN. 'RESSURE PSI
O 2 21-39 40
a 3 47-67 80
Figure 30. Density variation versus location insample tube from specimen 8, Dr 35 percent
.45
SAMPLE VARIATION FROM PLACED DENSITY36 1 T30 1t
181_ I
0-2 -i 0 2 3 4
0 -1
IL SMPLEVARIATION FROM PLACED DENSITYCM (CORRECTED FOR OVERBURDEN.-PRESSURE)
w3-- '
LZ
"(II,
S1 2-
W- 0
-5 -4 -3 -2 -1 0 2 3 4 5DRY DEN SIT Y 7 d C
LEGENDSAMPLE OPTH IN OVERBURDEN
SYMBOL NO SPECIMENU IN. PRESSURE, PSI
0 1 0-18 10
Figure 31. Density variation versus location insample tube from specimen 12, D 60 percent
46<
corrected to account for the overburden pressure applied. While Figures
25-31 exhibit considerable scatter, the general trend of the data ob-
tained at relative densities ranging from 20 to 60 percent indicates
that sampled density decreases with it,,,easing distance from the bottom
of thf sample tube. This trend is similar to results obtained in the
earlier work on a similar sand placed at D = 90 percent; however, inr
the earlier study results at D z 20 percent showed a reverse condi-2
rtion. Also, density corrections based on locaLion in the sampler tube
derived in the previous study are not consistet.L with results of this
investioation at intermediate relative densities, i.e., D from 30 tor
60 percent. The same sampling procedures were used in both studies, so
the difference in results may be attributed to test conditions (solid
wall versus sracked ring containers) or to the effect of the variables
cited earlier.
40. The preceding analysis illustrates the difficulty experienced
in separating test variables from an assessment of sampling accuracy.
In this instance, the corrections for density changes due to overburden
pressure are apparently very significant to the test results. The ran-
dom variables associated with placed density determinations are much
less susceptible to evaluation and cause some degree of uncertainty in
an assessment of sampling accuracy. However, an assessment can be made
from Figures 21 and 23; by definition, 95 percent of the sampling data
must fall within the range of -2 pcf. Within this range, sampling ac-
curacy is indicated to be ±3.4 pcf for density samples taken at relativ
densities D ranging from 20 to 60 percent. The linear -egressionr
data fits presented in Fig,'res 22 and 24 indicate that snmpling slightly
densifies the sand at low relative dgnsities (Dr < 40 per-cent) and
tends to loosen denser (0 > 50 percent) sand.r
24
PART V: CONCLUSIONS AND RECOMMENDATIONS
Conclusions
41. In the analysis section of this report, consi-crable atten-
tion was ei'en to the test variables which can influence test results,
and it was noted that placed dt-nsity at the time of sampling probably a
varied from +2.9 to -1.5 pcf from measured values due to the combined
effects of the test variables.
42. The sampled versus placed density comparisons presented sug-
gest that sampling accuracy using the techniques described is within
j ±3.4 pcf for 95 percent of the sampling conducted at relative densities
Dr ranging from 20 to 60 percent. However, it can also be concluded
I that a more meaningful assessment of sampling accuracy could have been
made had it been possible to exercise better placed density control
during the study; it is very probable that in this event the apparent
accuracy of sampling vw.uId have shown a corresponding improvement.
43. Despite the uncertainties cited, results of this and earlier
york exhibit generally similar trends. For instance, this and the
preceding work indicate that sampling tends to slightly densify loose
sand (D < 40 percent) and tends to slightly loosen denser sandr(Dr >50 percent). The plots presenting linear regression fits to
selected test data also lead to the conclsion that overburden pressure
corrections can significantly influence the results of density determi-
nations made with the sampling techniques described. More definitive
conclusions regarding sampling accuracy annot be advanced because of
Ithe uncertainty associated with the placed de sity results obtained
in this study.
Recommendations
44. The undisturbed sampling phase of the current study should
be extended with the following revisiors to test procedures:
a. An improved sand raining technique should be employed
48
so that density variations across the specimen can be re-
duced to the practical minimum (preferably ±0.5 pcf or
less).
III
b. A system to measure vertical deforma:tion of the specimen
should be added to the test apparatus.
i 49
REFERENCES
1. Goode, T. B., "Undisturbed Sand Sampling Below the Water Table,"
Bulletin No. 35, Jun 1950, U. S. Army Engineer Waterways Experiment
Station, CE, Vicksburg, Miss.
2. U. S. Army Engineer Waterways Experiment Station, CE, "Rotary Cone
Penetrometer Investigations," Potamology Report 18-1, Jun 1962,
Vicksburg, Miss.
3. Gibbs, H. J. and Holtz, W. G., "Progress Report of Research on?enetration Resistance Method of Subsurface Exploration," EM-314,
Sep 1952, Bureau of Reclamation, U. S. Department of the Interior,
Denver, Colo.
4. , "Research on Determining the Density of Sands by Spoon
Penetration Testing," Proceedings, Fourth International Conference
on Soil Mechanics and Foundation Engineering, London, Vol 1, 1957,
p, 35-39.
5. Bazaraa, A. R. S. S., Use of the Standard Penetration Test forEstimating Settlements of Shallow FoundAtions on Sand, Ph. D. Dis-
sertation, University of Illinois at Urbana, Urbana, Ill., Sep 1967.
6. deMello, V. F. B., "The Standard Penetration Test," Proceedin
Fourth PanAmerican Conference on Soil Mechanics and Foundation
Engineering, Vol 1, Jun 1971, pp 1-8o.
7. Peck, R. B. et al., "The Standard Penetration Test, Discussion,"Proceedings, Fourth PanAmerican Conference on Soil Mechanics and
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8. Cooper, S. S. and Sloan, R. C., "Development of a 1.22-m-Diam Dy-
namic Air Overpressure Soil Test Facility,' Miscellaneous ?aper
S-75-20, Jun 1975, U. S. Army Engineer Waterways Experiment Station,CE, Vicksburg, Miss.
9. Hvorslev, M. J., Memorandum for RecorJ, Subject: Use of a Stacked-Ring Test Bin in the Four-Foot Blast Load Generator, dated 30 Aug
1963, U. S. Army Et.,ineer Waterways Experiment Station, CE, Vicks-
burg, Miss.
10. Seaman, L. et al., "Stress Propagation in Soils; Final Report--Part III," SRI Project PHU-2917 (DASA 1266-3), May 1963, Stanford
Research Institute, Menlo Park, Calif.
ii. Hadala, P. F., "Sidewall Friction Reduction in Static and Dynamic
Small Blast Load Generator Tests," Technical Report S-68-4.
Aug 1968, U. S. Army Engineer Waterways Experiment Station, CE,
Vicksburg, Miss.
12. Hvorslev, M. J., "Subsurface Exploration and Sampling of Soils
for Civil Engineering Purposc,," Nov 1949, Report on a researchproject of the Cormmittee on Simpiing and Testing, Soil Mechanics
50
4I
and Foundation3 Division, American Society of Civil Engineers,sponsored by thc Engineering Foundation, Graduate School of Figi-neering, Harvard University, Cambridge, Mass., and U. S, Army
fEngineer Waterways Experiment Station, CE, Vicksburg, Miss.13. Office, Chief of Engineers, Department of the Army, "Soil Sampling,"
EM 1110-2-1907, 31 Mar 1972, Washington, D. C.
14. , "Laboratory Soils Testing," EM 1110-2-1906, 30 Nov 1970,Washington, D. C.
15. Sloan, R. C., "Dynamic Bearing Capacity of Soils; Dynamic Machineand Preliminary Small-Scale Footing Tests," Technical ReportNo. 3-599, Report 1, Jun 1962, U. S. Army Engineer Waterways Ex-
periment Station, CE, Vicksburg, Miss.
16. Bieganousky. W. A., "Laboratory Penetration Testing and Sampling"(in preparation), U. S. Army Engineer Waterways Experiment Station,CE, Vicksburg, Miss.
I,
91
Aspl PLAC9 Dlati..a
Colacede pf paa Pacd d
' pgh Dry' D~t IF"= S.L. Dry 0im 4ty OUT oaImu y~ FUSS 9Ijcd Pl~Domosv* Pwreu .pcipe
6,~ r acb.4 rc1..1
fp 80. d
2 4 6 5.40.595.9 1-1 -0.44
12 (i"059.1 1-2 96. 2.? 2.2
14 Salk .595.9 1-3 95.s 0.1 -0.4
N. I~fr.g...u 0. 9S.9 1-4 97.3 1.9 1.6
ID0.4 96.2 1-5 97.6 2.4 1.4
360.8 94.2 2-1 993 .9 1.1
0.4 I.i !- - II.S93.0 2-3 L6 . 20
240.9 91.0 )--1 99.0. .1
40 09 9.34 21 9. . 0.4
14 0 95.4 2.2 957 .2 0.312 .0 96.1 2- 94. 3. .
94.f 1. 95.0 1-1 92.7 -2.1 .
is S.1 95.0 1-1 95.4 1.0 4.1
40 2.2 9%.4 4-1 91.0 1.4 0.4
20 6, .~ 10 9S.9 2-1* 95. 2.2 0.3
46! 2 .0 0.9 *2.94 1.2 2 . 0.8
4s 1. 1.0 "2.s 31 95.7 1.2 2
92. 1.1 92.1 1-. 1.0 20.1
16 !-1 .. i. 93. 1 .2 -92. * 11 3. ! 1.4 0.1
92.8 2.7 15 1. 13 -.
92.. 1.8 91.4 03 7 .%4.44 9 .91.1 .. .2
91. * 1.9 1.- --
12 967 .3 -90 12 '. 0.9 -1.216D 9..1 094 1I 9. . .2
in 99.0 3.4 991 1016. .
36 984.1 0.5 98 .. 128 ~ 2l
o29. .5 93.8 3- 9 160.4
46 9. 0.$ 98.* 6-1 79 -0. 1.
5;.7 0.6 "8. i -7 9.2 -.-40 7.10.1 97.7 4- 7. 0. .7
44 p.90.,b 99.5 4~ 7.2 .4.? 2.
7: 9. 0.4 95.1 - .
55 4 98.; 0.5 98.6 - 96.1 0.0 U.S
.598.2 "A 9. 2.0 1.S
n9 97.8 0. 93 :-1 99.9 2.11.
97. 0. 961 21 9.9 0.2 3A
42 972 0. 98.2 3- 7.8 0.4 0.
0.6 182 -3 9.3 -0 -.
4) 96.3 .194 - 97.5 -0.6 -1.9
64 9. .19. -) 9. 0.5 -2.4
17.a~ 4 -.. . ----
0.8 . . 46 '. 0
16 - -... -. -.
1.9 0.1 9.0 2-! 94.2 0.9 -0.2106.7 - -- -- -- --
12 6 95.. 0.7 9"A 1-1 -- -.
12 913 .7 "A. 1-: 28 .. -0.:
60 9461. 1.n 1-2 9.1 -2 -. 4
22 40 9.4. . 121 9. 10-.
12 9.9 0.194 12 994 0 ~ -.
24 6. 0.1 99.1 -2 .8.9 4.7
4. --- - .-
le 98C0.OPY - --
,Best AvailableCp
DASHED LINE INDICATESAPPROXIMATE FORCE ON
SAMPLER x 103
KG 0 I 2 3
RELATIVE DENSITY, % I I I Ii
CM IN 30 40 50 s0 70 LE 0 2 4 6 6
00
2';DRIVE NO.
40 . 3
z eo ; - --..-
I--A
in 30 Z- AVR.C i-...AVERAG r---
a. 80- PLACED0 DENSITY. 2Ia. __ __ _ __- -- -
0 36 -
30 . .. . -*-2 --
-J42
120 0
800
LB/CU FT 9 5 96 97: 789 I 0 102 -4 04 8 12
1 0 - - *
-005 005 0.15
I RYV EST tY. DRY DENSITY, "
PLACMEN DESITYANDDENITY VARIATION FROMOF SAMPLED INCREME'__TS VDEPTH PLACED DENSITY
COMPUTED FROM "tOTAL wEIGHT AOVOLUME OF SPECIMEN
LEGEN DENSITY TEST RESULTS, PLCI ENITY, REID BEDFORD SANDI SAMPLED DENSITY
1-3 FIRST SAMPLE-THIRD NOMINAL RELATIVE DENSITY1 Dr = 400SAMPLE INCROMENT (SPECIMEN 2 )
13< PLATE 1
-- 17
DASHED LINE INCICATESAPPROXIMATE FORCE ON
SAMPLER x 103
KG 0 ! 2 3
RELATIVE DENSITY, % I I I ICM IN 20 30 40 50 60 70LB 0 2 4 6 a
20 120
12- -- ~----4.-
40 1-3 0
5 _w AVERAGEa. 30 PLACED--- - -__
6. 0 DENS171Y 0 --oz0 1220 3
I ,o. ,I
00 2-3 010
120
C L 48-0 - 442---
60 Ic . 4-2
180L 72 _____ ________ ___
LB/CU FT VI 92 93 94 95 go 97 98 99 100 101 -4 0 A a 12
1 . . I I I I I I I . i II . . ' ' __GM/CC 1.50 155 160 -0.05 0 0.05 0.15
DRY DENSITY, Yd DRY DENSITY, yd
PLACEMENT DENSITY AND DENSITY VARIATION FROM
OF SAMPLED INCREMENTS VS DEPTH PLACED DENSITY
COMPUTED FROM TOTAL WEIGHT AND VOLUME OF SPECIMEN
LEGEND DENSITY TEST RESULTSI PLACED DENSITY REID BEDFORD SAND* SAMPLED DENSITY
3SMPSAMPETYD NOMINAL RELATIVE DENSITY, Dr=35%1-3 FIRST SAMPLE -THIRD
SAMPLE INCREMENT (SPECIMEN 4 )
PLATE 2 . ,
DASHED LINE INDICATESAPPROXIMATE FORCE ON
SAMPLER x 103
KG 0 I 2 3
RELATIVE DENSITY, % I I I ICM IN 0 10 20 ::a 40 50 LEI 0 . 4 6 8
I0 -- I |
1,l-220._ I\
PLACED4o~~~ - TD .'*l ,40 DENS17* 1- 0
0
w 60 -- 24
It u 2-3
U. so -0 2 c
010o O- 2-3 '0
_ J 42-- ---- I
120 -r 48 .. ..- _I
3-i
40 -5 RVE NO. 0
160 -
180 L 72_____ ,___ _,_._.
"LB/CU FT 88 89 90 91 92 93 94 95 96 97 96 -4 -2 0 2 4, , ' , I I , I . .I , I . , . . I . . I
GM/CC 1.45 I 50 1.55 -0.05 0 005
DRY DENSITY, Yd DRY DENSITY, fd
PLACEMENT DENSITY AND DENSITY VARIAT!ON FROMOF SAMPLED INCREMENTS VS DEPTH PLACED DENSITY
I' FROM BOx DENSITY MEASUREMENTS
LEGEND DENSITY TEST RESULTSPLACED DENSITY REID BEDFORD SAND
* SAMPLED DENSITY
1-3 FIRST SAMPLE -THIRD NOMINAL RELATIVE DENSITY, Dr= 20%SAMPLE INCREMENT (SPECIMEN 5 )
I
". ":PLATE 3
RELATIVE DENSITY, % DRIVECM IN 0 0 20 30 40 50 60 70 80 90 NO.
0
20 I '-
12 - --- - I- - -I40 -Io 1-3 0*118
1-4 0
I60 24 - -
80PLCELNT EIYD ENSIT VAITO 0RO
i. 80- LACED D'S' EDBDODSN
0 AEEslrES
0 3 [ ---- 03: 1000
12 -~ 482 - -1
0.w
4 54 - 42 {-0
140 -
LB/CU FT 88 88 90 92 94 98 98 100 102 104 106 -15 -10 -5 0 5
cG.'CC 140 I 50 LGO 1 70 -0.20 -010 0
DRY DENSITY, Yd DR D)ENS''Y, 'f
PLACEMENT DENSITY AND DENSITY VARIATION FROMOF SAMPLED INCREMENTS VS DEPTH PLACED DENSITY
II FROM BOX DENS11v MEASUPEMENTS
LEGEND DENSITY TEST RESULTSIPLACED DENSITY REID BEDFORD SAND
4 SAMPLED DENSITY NWA EAIEDNIY r 51-3 FIRST SAMPLE -THIRD NMNLRLTV ESTDZ50SAMPLE INCREMENT (SPECIMEN 6)
PLATE 4 5w
-11
I
I
RELATIVE DENSITY, % DRIVECM IN 30 40 50 60 70 NO
2060
12 - ,---4- q1 -2, I
40 DENSI TY* *
) 0 PLACD3-
U))
, w 0 - 24.- . - t-- 2----+ - '
t80 -37A I 0
38
3:100 4240
-31 I, _I 120 48 -- ,-- ---.----
L/U T929 4 9 019 B 9 O O 12- 4 0 • 8!
140 -- 1
60
8 80 ---
180 721 1J1LB/CU FT 9293 94 9590e 97986 99@100 101 102 -6 -4 0 a a
GM/CC 1.50 1.55 I 60 -0.10 0 0.10
RY DENSITY, Yd DRY DENSITY? yd
PLACEMENT DENSITY AND DENSITY VARIATION FROMOF SAMPLED INCREMENTS VS DEPTH PLACED DENSITY
FROM BOX DENSITY MEASUREMENTS
LEGEND DENSITY TEST RESULTSI PLACED DENSITY REID BEDFORD SAND
* SAMPLED DENSITY1-3 FIRST SAMPLE-THIRD NOMINAL RELATIVE DENSITY1 Dr = 55%
SAMPLE INCREMENT (SPECIMEN 7 )
PLATE 5
RELATIVE DENSITY, % DRIVECM IN I0 20 30 40 50 60 NO
20 -
1-2I1 0
12 I 1-3
40 -
o T I
60 - 2 L
0O 4;> - v :
(22
______ uc -", Iorocr .I'
I- 120 -_j 481 -.P0 0 -° TT OVER G
,IoI I C i I o , I
GM/CC 1.45 IO I 55 1.60 -0.02 0 0.02
DRY DENSITY, Yd DRY DENSiTY, T d
PLACEMENT DENSITY AND DENSITY VARIATION FROM=OF SAMPLED INCREMENTS VS DC' TH PLACED DENSITY
tFROMA 80x DENSITY€ MEASUREMENTS
LEGEND DENSITY TEST RESULTSI PLACED DENSITY REID BEDFORD SAND(= SAMPLED DENSITY 3-3 FIRST SAMPLE-THIRD NOMINAL RELATIVE DENSITY 1 Dr 35%
SAMPLE INCREMENT (SPECIMEN 8 )
PLATE 6 58
RELATIVE DENSITY, % DRIVECM IN. 5 0 60 70 80 90 NO.
0 r F7T I -!6 -I6i! PLACED OCN, sry* 0
20 1I 4--6 EI
40 - is,1-31
. 0 - 24-
0 I I 2-0
0.--i~III 2-2110 36
oo 3 2-30O
w 42 _-4
, 20 ,w03-
5443 -I 3- --- 0143
I, , ! i ' I I 3
ISO I; , I i
ISO 72LB/CU FT 27 ge 99 l00 101 102 103 104 105 106 107 -2 0 2 4 G
.. . * I I ,*, .., .. I !GM/CC 1.60 1.65 1.70 -003 0 0.05
DRY DEINJSITY, Yd DRY DENSITYf d
PLACEMENT DENSITY AND DENSiTY VARIATION FROMOF SAMPLED INCREMENTS VS DEPTH PLACED DENSITY
It I FROM Box DENSITY MEASUREMENTS
LEGEND DENSITY TEST RESULTSI PLAC o DENSITY REID BEDFORD SAND
SAMPLED DENSITY1-3 FIRST SAMPLE-THIRD NOMINAL RELATIVE DENSITY1 Dr=60%
SAMPLE INCREMENT (SPECIMEN 12 )
5.4: "PLATE 7
I!
IIIi
APPENDIX A
1
:ij
PETROGRAPHIC EXAMINATION OF
I REID-BEDFORD MODEL SAND
60-
DEPARTMENT OF THE ARMYWATERWAYS EXPERIMENT STATION. CORPS OF ENGINEERS
P 0 BOX 631
vICKSBURG. MISSISSIPPI 39180
SIPLY M91.. To WESSG 23 April 1974
MEMORANDUM FOR: Dr. W. F. Marcuson
SUBJECT: Petrographic Examination of the Reid-Bedford Model Sand
General
1. A sample of the Reid-Bedford model sand was analyzed by petro-graphic and statistical techniques for the purpose of determining grossmineralogy, degree of grain roundness, and the basic statistical param-eters exhibited by this sediment.
Size-distribution statistics
2. Grain-size data obtained from the gradation curve were recalculatedin phi (0)* units and plotted on probability paper. The resulting curvepermitted the mean and median grain size, standard deviation, skewness,and the kurtosis to be calculated. These parameters are summarizedbelow.
a. Mean grain size: 2.00 0 z 0. Z5 mm. This corresponds to thedivision between medium and fine sand.**
b. Median grain size: 2.00 0 0.25 mm.
c. Standard devi.ation: 0.50 0 : 0.71 mm. The following classifica-tion is used here:
Very well sorted: . 0. 35 0 .Well sorted: 0. 35-0. 50 0.Moderately well sorted: 0. 50-0.71 0.Moderately sorted: 0.71-1.00 0.Poorly sorted: 1. CO-2. 00 0.
Thus the Reid-Bedford sand is well to moderately well sorted.
* mm = 2 "0** Wentworth scale.
WESSG 23 April 1974SUBJECT: Petrographic Examination of the Reid-Bedford Model Sand I
I
d. Skewness: -0.03 where|+0.3 to +1.00: strongly fine skewed+0. 1 to +0. 3: fine skewed
-0. 1 to +0. 1: near symmetrical
-0.3 to -0. 1: coarse skewed, etc.The Reid-Bedford is, therefore, nearly symmetrical in distribution.
e. Kurtosis: 1.54. This value indicates a verb leptokurtic curvewhere
h 0.67 . very platykurtic
0.67 to 0.90 -platykurtic0.90 to 1. 11- mesokurtic1. 11 to 1.50---leptokurtic
1. 50 to 3.00 -- $very leptokurtic
Petrography
3. General. The sand was examined by both nenpolarizing binocularand polarizing microscopes. The nonpolarizing type facilitates theexamination of the coarser particles, whereas the finer fractions re-quire polarized light. In order to determine any variation in roundingand mineralogy with respect to grain size, the sample was sieved
through the No. 35, 60, 120, 200, and 300 mesh sieves. Grain mountsusing Lakeside 70 were prepared for the No. 120, 2d0, and 300 mesh
splits and for the pan fraction.
4. Particle morphology (general). Two important elements of particlemorphology are sphericity and roundness. Sphericity relates to apartizle's equidimensionality. whereas roundness is a parameter thatdescribes the extent of "rough edges" on the particle surface. Theseparameters are not necessarily related; a prismatic grain, for example.
could have a highly rounded surface. Quantitative values may be deter-mined for both sphericity and roundness, but this is a time-consuming
task (especially for sphericity) and was not done here. Instead, round-ness was estimated from the index forms shown below.
A 8 C D E
RoundnDes chL,&c. A: Angular. I: Subangular C: Subroundelt. D: Rounded.E: Well Rounded.
6< 2
I5. Preliminary examination of gross sample with nonpolarizing,binocular mi.zroscope. The sand consists predominantly of tan to light
brown quartz sand. Two types may be distinguished as (a) a clear, un-N'eathered, subangular type, and (b) a cloudy, less angular variety.These two types comprise roughly subequal rroportions of the sample.
Possibly some of the cloudy grains are felds.ar. Moscovite mica ispresent and comprises less than 5 percent of he sample; the mica isconsiderably coarser (,- 1. 00 nrn) than the accompanying quartz.Identifiable 'heavy" minerals include tourmaline, garnet, and p,,.-umedamphibole-pyroxene minerals; no magnetic minerals were detected. Theheavies are estimated to comprise no more than 1-2 percent of the total
sample. The sample appears free of visible organic matter.
6. Fxamination of sieve splits. Examination of sieve splits consistedof the following sieves:
a. Sieve No. 35 (nonpolarizing). Predominantly subrounded tosubangular grains of quartz; varieties include both clear and cloudy.The cloudy grains appear to have polished surfaces. Chert. ferro-
mags. a sltstone rock fragment, and calcite concretions compriseapproximately 1 or 2 percent of the split.
b. Sieve No. 60 (nonpolarizing). Very similar to sieve No. 35except that there is an apparent slight increase in heavy mineral con-centration (ferromags. garnet, etc. I
c. Sieve No. 120 (polarizing). Rounding: subangular: grain countrevealed approximately 88. 5 percent auartz and 11. 5 percent feldspar.Although no other minerals were encountered in the count traverses.the nonquartz or feldspar content is probably around I percent or less.
d. Sieve No. 200 (polarizing microscope). Rounding: subangular:mineralogy is 12. 3 percent quartz, ;. 6 percent feldspar, and 2. 1 per-cent opaques, mica. chert, and unknowns.
e. Sieve No. 300 (polarizing mcroscopel. Roundng: subangular:mineralogy is 7=,. ; percent quartz. 15. 3 percent feldspar. 4. t percentopaques, 1.8 percent chert, 2.8 percent calcite, and unknowns.
f. Pan fraction (polarizing microscopel. Rounding: suban.ular:mineralogy estimated to be 6, percent quartz. 25 percent feldspar.and 10 percent "heavies (orZaques. 7ircon. rutale. etc. I and calcite.
3
WESSG Z3 April 1974SUBJECT: Petrographic Examination of the Reid .Bedford Model Sand
Mineralogical summary
7. Table 1 below summarizes the mineralogical composition of thesample and relates this to grain size.
Table 1
Mineralogical Composition
Sieve Fraction of Percent of Total SampleNo. 0 mm Total Sample Quartz Feldspar Other*
35 +1.00 0.500 0.050 4.5 0.4 0.1
60 -2. JO 0.250 0.450 40.5 3.2 1.4120 +3.00 0.125 0.465 41.2 5.4 0.5200 -3.75 0,074 0.021 1.9 0.1 tr
300 -L4.40 0.046 0.002 0.2 tr trPan 0.012 0.8 0.3 0.1
Totals 1.000 89.1 9.4 2. 1
*Other includes calcite, mica. "heavies," and ferromags.
8. The mineralogy of the composite sample may be summarized as:quartz, 89 percent: feldspar. Q percent; and other minerals, 2 percent.Although no detailed analysis was performed on the heavy mineral suite(specific gravity 2 2.8), the apparent low concentration of these min-
erals V 2 percent) indicates that the assumed specif-ic gravity of 2. 65is approximately correct.
Particle morphology
1). The degree of rout ding is, in part. a function of size: ordinarily thecoarser particles exhibi; better rounding than the finer ones. This is thecase with the Reid-Bedfo-d. AlIthough the coarser particles are classedas subangular to subrour ded, the finer particles ,less than 0. 25 mrn) aresubangular. The overall classif:cation is subangular to subrounded.
64<
II HE- - ____
WESSG 23 April 1974SUBJECT: Petrographic Examination of the Reid-Bedford Model Sand
10. With respect to sphe ricity, the sample consists of considerablepramatic or tabular quartz grains, some of which exhibit sharp edgesand conchoidal fracture surfaces. These features are more charac-teristic of the minus 0.25-mm fraction. TLe photomicrographs shownin figs. 1-3 illustrate partricle morphology (Incls 1-3).
Conclusions and recommendations
11. The Reid-Bedford model sand is classified as: well to moderatelywell sorted, near symmetrical, very leptokurtic, medium to fine sandwhose mineralogy consists of 89 percent quartz, 9 percent feldspar, and2 percent calcite, ferromags, and "heavies. The. rounding class is sub-rounded to subangular.
12. In order to more adequatey determine the degree of rounding, itis recommended that scanning electron microscopy be performed onselected sieve splits in the future.
3 Incl DAVID M. PATRICKas Research Geologist
Engineering Geology Division
65<5
- - __(a)
0. 2 mrI
(b)
0. 125 m
Fig.1. hoto icrgraps o Rei-Befordsantake wih nnpoarizng icrscoe: a) N. 6 sive nd () N. 10 seve
404
0. 074 mm
(b)
0. 074 mm
Fig. 2. Photonicrographs of Reid-Bedford sand, No. ZOO sieve:(a) nonpolarizing microscope and (b) petrographic microscope,
plain light.
0.046 nun
(b)
0. 046 mm
Fig. 3. Photomicrographs of Reid-Bedford sand;petrographic microscope and plain light:
(a) No. 300 sieve and (b) passing No. 300 sieve.
1w
Jam- ms.t wtfo--3, umwqk (illb),awe 15 husm, 1973, a ftesqmle catelq erSmIn u of~ar at~ fars r t 12 l.~op c below.
Cooper, Stafford SLaboratory investigation of undisturbed sampling of
cohesionless material below the water table, by StaffordS. Cooper. Vicksburg, U. S. Army Engineer WaterwnvsExperiment Stition, 1976.
1 v. (various paging) illus. 27 cm. (U. S. Water-ways Experiment Station. Research report S-76-t)
Prepared for Office. Chief of Engineers, V. S. Army.Washington, D. C., under CWtS 31145.
Includes bibliography.
I. Cohesionless soils. 2. Laboratory tests. 3. Sands.4. Soil test specimens. 5. Undisturbed soil samples.I. U. S. Army. Corps of .ngineers. (Series: U. S.Waterways Experiment Station, Vicksburg, Miss. Researchreport S-76-1)rA7.W34r no.S-'A-I
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